A frequency converting section (101), which is included in a liquid crystal display apparatus, generates an output video signal by inserting one non-image signal, which is to be concurrently written into pixels on L (L is an integer equal to or greater than two) gate lines of the liquid crystal panel, for one line, between image signals composing an input video signal, for corresponding L lines, and adjusting a number of horizontal scanning periods of the output video signal in a vertical blanking period so that a number of horizontal scanning periods composing one frame period is (L+1)×(2N+1) (N is an integer). Thus, when anti-back-transition driving is performed using a liquid crystal panel in OCB mode, it is possible to minimize increase in a driving frequency, prevent irregularity of brightness caused by AC driving of the liquid crystal panel, and reduce a cost.
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11. A liquid crystal display apparatus driving method for displaying video by driving a liquid crystal panel having a plurality of source lines and a plurality of gate lines, based on an input video signal, the method characterized by:
generating an output video signal by inserting one non-image signal, which is to be concurrently written into pixels on L (L is an integer equal to or greater than two) gate lines of the liquid crystal panel, for one line, between image signals composing the input video signal, for corresponding L lines, and adjusting a number of horizontal scanning periods of the output video signal so that a number of horizontal scanning periods composing one frame period is (L+1)×(2N+1) (N is an integer);
driving the liquid crystal panel based on the output video signal; and
increasing/decreasing a number of horizontal scanning periods included in a vertical blanking period, thereby adjusting a number of horizontal scanning periods composing one frame period.
1. A liquid crystal display apparatus for displaying video by driving a liquid crystal panel based on an input video signal, the liquid crystal display apparatus comprising:
a liquid crystal panel having a plurality of source lines and a plurality of gate lines;
a frequency converting section for generating an output video signal by inserting one non-image signal, which is to be concurrently written into pixels on L (L is an integer equal to or greater than two) gate lines of the liquid crystal panel, for one line, between image signals composing the input video signal, for corresponding L lines, and adjusting a number of horizontal scanning periods of the output video signal so that a number of horizontal scanning periods composing one frame period is (L+1)×(2N+1) (N is an integer); and
a driver for driving the liquid crystal panel based on the output video signal generated by the frequency converting section, wherein
the frequency converting section increases/decreases a number of horizontal scanning periods included in a vertical blanking period, thereby adjusting the number of horizontal scanning periods composing one frame period.
2. The liquid crystal display apparatus according to claim 1, wherein
the liquid crystal panel is a liquid crystal panel in OCB mode, and
the non-image signal is a signal for applying a predetermined high voltage to a liquid crystal of the liquid crystal panel so as to prevent a back-transition.
3. The liquid crystal display apparatus according to
4. The liquid crystal display apparatus according to
5. The liquid crystal display apparatus according to
a period determining section for determining whether or not an image signal supplied to the frequency converting section corresponds to the adjusting period, based on a synchronizing signal synchronized with the input video signal; and
a selector for supplying, to the frequency converting section, either a dividing clock number for an adjusting period in a vertical blanking period or a different dividing clock number for periods other than the adjusting period in one frame period, based on results determined by the period determining section.
6. The liquid crystal display apparatus according to
the liquid crystal display apparatus further characterized by comprising a dividing clock number calculating section for calculating, based on a number of horizontal scanning periods included in a period from a start of an active video period to an input of a vertical synchronizing pulse, a dividing clock number corresponding to a following adjusting period.
7. The liquid crystal display apparatus according to
8. The liquid crystal display apparatus according to
9. The liquid crystal display apparatus according to
10. The liquid crystal display apparatus according to
12. The liquid crystal display apparatus driving method according to
13. The liquid crystal display apparatus driving method according to
making determination, based on a synchronizing signal synchronized with an input video signal, whether or not each image signal included in the input video signal corresponds to the adjusting period;
selecting either a dividing clock number for an adjusting period or a different dividing clock number for periods other than the adjusting period in one frame period, based on the determination results; and
generating the output video signal based on the selected dividing clock number.
14. The liquid crystal display apparatus driving method according to
the adjusting period is a period from an input of a vertical synchronizing pulse to an end of a vertical blanking period, and the method further characterized by:
calculating a dividing clock number, based on a number of horizontal scanning periods included in a period from a start of an active video period to an input of a vertical synchronizing pulse, the dividing clock number corresponding to a following adjusting period.
15. The liquid crystal display apparatus driving method according to
16. The liquid crystal display apparatus driving method according to
17. The liquid crystal display apparatus driving method according to
18. The liquid crystal display apparatus driving method according to
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The present invention relates to a liquid crystal display apparatus and, particularly, relates to a liquid crystal display apparatus suitable for display of moving images using a liquid crystal panel, and suitable for a case where a liquid crystal panel in Optically self-Compensated Birefringence (OCB) mode is used.
Many liquid crystal display apparatuses are used as display devices for computers, etc., and are expected to be widely used for TV in future years. However, a liquid crystal display panel in Twisted Nematic (TN) mode, which is now widely used, has some shortcomings, namely, narrow viewing angles and inadequate response speeds. Consequently, there are some major problems to be solved, for example, reduction in a contrast due to parallax or blurred outlines at the time of displaying moving images, in order to use the liquid crystal panel in TN mode for TV.
In recent years, research on OCB mode, which is replacing the above-described TN mode, has been conducted. The OCB mode of operation allows for wide viewing angles and enhanced response speeds, thereby being more suitable for displaying moving images than the TN mode.
2602 indicates a gate driver for supplying a gate pulse, which controls the ON/OFF states of the TFTs 2604, to the gate lines X1 to Xn. The gate driver 2602 synchronizes with data supply to the source lines Y1 to Yn, and sequentially applies a potential to the gate lines X1 to Xn, which turns the states of the TFT 2604 ON. 2601 indicates a source driver for controlling a potential of the pixel electrode. A difference between a potential of the pixel electrode controlled by the source driver 2601 and a potential of the counter electrode controlled by the counter driving section 2603 is a voltage to be applied to the liquid crystal, and transmittance of each pixel 2605 is determined based on the above-described voltage.
Now, in a case where the liquid crystal panel in OCB mode is used, special processing, which is not performed for the TN mode, is required at the first stage of commencing image display. A state of OCB cells can be either a bend configuration or a splay configuration. In order to display an image on the liquid crystal panel in OCB mode, the OCB cells have to be in a bend configuration state. However, in general, the OCB cells are in a state of a splay configuration. Therefore, a state of the OCB cells has to be changed from a splay configuration to a bend configuration for displaying an image. Hereinafter, the above-described state change from a splay configuration to a bend configuration is referred to as a “transition”. In order to cause a transition of the OCB cells, special processing, for example, applying a high voltage for a predetermined period of time, is required. However, this processing is not directly related to the present invention, and therefore not further described herein.
After the above-described special processing causes the state of OCB cells to make a transition to a bend configuration, image display becomes possible. However, if a voltage equal to or greater than a predetermined level is not applied to the OCB cells for a period equal to or greater than a predetermined period of time, the state of the OCB cells returns back from a bend configuration to a splay configuration. Hereinafter, the above-described state change from a bend configuration to a splay configuration is referred to as a “back transition”. Thus, in order to continue image display using the liquid crystal panel in OCB mode, it is necessary to prevent a back transition. A back transition can be prevented by applying a high voltage to the OCB cells on a regular basis, as disclosed in Japanese Patent Laid-Open Publication No. H11-109921 and Japanese Liquid Crystal Society Journal, Apr. 25, 1999 (Vol. 3, No. 2) P.99 (17) through P.106 (24). Hereinafter, such a driving scheme of a liquid crystal panel, in which a high voltage is applied to the OCB cells on a regular basis, is referred to as “anti-back-transition driving”.
Now, as is well known, in a commonly-used liquid crystal panel typified by the OCB mode and the TN mode, a direct voltage applied to liquid crystal cells causes a problem such as burn-in. Therefore, when the liquid crystal panel is driven, it is necessary to perform so-called AC driving, in which polarity of the voltage applied to the liquid crystal cells is alternately inverted. This is also applied to a case where the liquid crystal panel is driven by the above-described anti-back-transition driving. However, in the above-described Japanese Patent Laid-Open Publication No. H11-109921 and Japanese Liquid Crystal Society Journal, a structure or an operation of a liquid crystal display apparatus in a case where an AC driving scheme is used for the anti-back-transition driving is not specifically described, and the above-described documents do not reveal a concrete method to apply an AC driving scheme to the anti-back-transition driving.
Now, the above-described documents disclose a scheme in which source drivers are placed on upper and under sides or a scheme in which driving frequency is doubled, in order to alternately write an image signal and a high voltage signal (a signal for periodically applying a high voltage to OCB cells). However, those schemes have a problem such as increase in cost because there is a need to use two source drivers, or inadequate writing of signal into OCB cells due to reduced signal writing time caused by the doubled driving frequency. Therefore, inventers of the present invention realize anti-back-transition driving by which increase in driving frequency is minimized. Hereinafter, as a related art of the present invention, a liquid crystal display apparatus to which anti-back-transition driving is applied will be described.
In
In this liquid crystal display apparatus, one image signal included in an input video signal and one non-image signal which is irrelevant to the input video signal are written into each pixel on the liquid crystal panel 2703 during one frame period. Here, the non-image signal is a signal for applying a high voltage to OCB cells in order to prevent a back transition. In order to realize the above-described writing, it is necessary to insert the non-image signal between the image signals composing the input video signal. Therefore, the frequency converting section 2701 of this liquid crystal display apparatus generates an output video signal by inserting one non-image signal for every four image signals (image signals corresponding to four lines) of an input video signal, and transfers it to the source driver 2601. At the same time, the frequency converting section 2701 also performs frequency conversion because mere insertion of the non-image signal could change a length of one frame period. That is, in order to transfer five signals including four image signals and one non-image signal to the source driver within a time period in which four image signals are input as an input video signal (that is, within four horizontal scanning periods), 1.25 times frequency conversion is performed.
In
An input/output characteristic of the source driver 2601 is shown in
In
During a period T1_0 in a following frame period, the gate pulses P5 to P8 become HI at the same time, and the non-image signal in negative polarity (polarity opposite to that in the previous frame) is written into pixels on the gate lines GL5 to GL8. During a following period T1_1 trough T1_4, the gate pulses P1 to P4 sequentially become HI, and image signals S′1 to S′4 in negative polarity (polarity opposite to that in the previous frame) are sequentially written into the pixels on the gate lines GL1 to GL4.
As described above, according to the liquid crystal display apparatus shown in
Now, the anti-back-transition driving performed by the above liquid crystal display apparatus (that is, anti-back-transition driving by which increase in a driving frequency is minimized by concurrently writing a non-image signal into a plurality of gate lines) restricts the number of horizontal scanning periods composing one frame period.
For example, in a scheme typified by the above-described liquid crystal display apparatus, in which a non-image signal is concurrently written into four gate lines, the number of horizontal scanning periods composing one frame period has to be an odd multiple of five at the time of completion of frequency conversion (that is, in an output video signal). In the example of
In order to prevent the above-described irregularity of brightness, the number of horizontal scanning periods has to be adjusted. However, mere increase or decrease of the number of horizontal scanning periods causes a time lag between writing and reading of an image signal into/from the line memory 2802 as shown in
Therefore, an object of the present invention is to provide a low-cost liquid crystal display device capable of performing anti-back-transition driving by which increase in a driving frequency is minimized and display of a good-quality video by reducing the occurrence of irregularity of brightness is possible.
To achieve the above objects, the present invention has the following aspects. Note that notes in parentheses indicate exemplary elements which can be found in the embodiments to follow, though such notes are not intended to limit the scope of the invention.
A liquid crystal display apparatus of the present invention displays video by driving a liquid crystal panel based on an input video signal, comprising: a liquid crystal panel (107) having a plurality of source lines and a plurality of gate lines; a frequency converting section (101) for generating an output video signal by inserting one non-image signal, which is to be concurrently written into pixels on L (L is an integer equal to or greater than two) gate lines of the liquid crystal panel, for one line, between image signals composing the input video signal, for corresponding L lines, and adjusting the number of horizontal scanning periods of the output video signal so that a number of horizontal scanning periods composing one frame period is (L+1)×(2N+1) (N is an integer); and a driver (105) for driving the liquid crystal panel based on the output video signal generated by the frequency converting section, and the frequency converting section increases/decreases a number of horizontal scanning periods included in a vertical blanking period, thereby adjusting the number of horizontal scanning periods composing one frame period. Thus, the non-image signal is regularly inserted, and irregularity of brightness does not occur even if AC driving is performed for the liquid crystal panel. Furthermore, the number of horizontal scanning periods is adjusted during the vertical blanking period, whereby it is not necessary to use a memory concurrently storing image signals corresponding to two or more lines. Also, it is possible to adjust the number of horizontal scanning periods without affecting video displayed on the liquid crystal panel. Note that “one frame period” is a period including not only an active video period but also a following vertical blanking period. Also, “the number of horizontal scanning periods composing one frame period” translates to the number of periods chopped by horizontal synchronizing signals in one frame period. Specifically, in
Note that “a back-transition” in claims is a phenomenon in which a state of OCB cells is changed from a bend configuration to a splay configuration. Also, “an adjusting period included in the vertical blanking period” does not rule out a case where the vertical blanking period coincides with the adjusting period.
Hereinafter, with reference to the drawings, various embodiments of the present invention will be described.
(First Embodiment)
In
To the liquid crystal display apparatus, an input video signal and a corresponding input synchronizing signal (including a horizontal synchronizing signal and a vertical synchronizing signal) are supplied. The period determining section 103 determines a vertical blanking period based on the input synchronizing signal. Based on the determination results by the period determining section 103, the selector 104 selects a dividing clock number (a dividing clock number A for the vertical blanking period or a dividing clock number B for other interval), and supplies it to the frequency converting section 101. The frequency converting section 101 performs a frequency converting process for the input video signal and the input synchronizing signal, and further inserts, at predetermined intervals, anon-image signal (a signal for applying a high voltage to OCB cells in order to prevent a back-transition) between image signals (video signal corresponding to one line) included in the input video signal. Note that, in the present embodiment, it is assumed that the frequency converting section 101 performs 1.25 times frequency conversion, and generates an output video signal by inserting one non-image signal foe every four image signals.
In
Hereinafter, for the sake of simplicity of the descriptions, a specific operation of the liquid crystal display apparatus will be described, by taking an exemplary case in which the number of horizontal scanning periods composing one frame period in an input video signal is 50 (among these, the number of horizontal scanning periods in an active video period is 40, and the number of horizontal scanning periods in a vertical blanking period is 10). Note that it is assumed that one frame period is 20 ms.
In this case, if 1.25 times frequency conversion is simply performed for the input video signal, the number of horizontal scanning periods composing one frame period in the output video signal becomes 50×1.25=62.5, which is not an odd multiple of (L+1) (note that, in the present embodiment, L=4). As a result, irregularity of brightness occurs. For that reason, during the active video period, the frequency converting section 101 changes the number of horizontal scanning periods in the active video period from 40 to 50, and changes the number of horizontal scanning periods in the vertical blanking period from 10 to 15. As a result, the number of horizontal scanning periods composing one frame period in the output video signal becomes 50+15=65, which is an odd multiple of (L+1).
In order to realize the above-described operation of the frequency converting section 101, in the present embodiment, a different dividing clock number is used in the active video period and in the vertical blanking period.
Assume that a horizontal dot clock number of the input video signal is 100, a frequency of the writing clock of the line memory 202 becomes 100×50/0.02=250 kHz. In the frequency converting section 101, 1.25 times frequency conversion is performed, and a frequency of the reading clock of the line memory 202 becomes 250×1.25=312.5 kHz.
The active video period is 20×40/50=16 ms, and the number of horizontal scanning periods included in the active video period in the output video signal is 50, whereby the necessary dividing clock number in the active video period is 312.5×16/50=100.
On the other hand, the vertical blanking period is 20×10/50=4 ms, and the number of horizontal scanning periods included in the vertical blanking period in the output video signal is 15, whereby the necessary dividing clock number in the vertical blanking period is 312.5×4/15=83 (fractional portion is truncated) Here, for the sake of simplicity of the descriptions, it is assumed that the fractional portion is truncated, but frequency division may be performed while keeping decimal precision (a method thereof is well-known, and therefore is not further described).
That is, what is needed is to previously set the dividing clock number A and the dividing clock number B, as shown in FIG. 1, at 100 and 83, respectively. The selector 104 selects the dividing clock number A (100) for the active video period, and selects the dividing clock number B (83) for the vertical blanking period. The control signal generating section 201 of the frequency converting section 101 generates an output synchronizing signal and an output video signal, based on the dividing clock number supplied from the selector 104, for outputting. Signal waveforms indicating such operation of the frequency converting section 101 are shown in
In
As such, according to the first embodiment, the frequency converting section 101 generates an output video signal by inserting one non-image signal, which is to be concurrently written into pixels on L gate lines of the liquid crystal panel 107, for one line, between image signals composing the input video signal, for corresponding L lines, and adjusting the number of horizontal scanning periods of the output video signal so that a number of horizontal scanning periods composing one frame period is (L+1)×(2N+1) (N is an integer). Therefore, irregularity of brightness does not occur even in a case where a non-image signal is regularly inserted and AC driving is performed for the liquid crystal panel 107.
Note that, in the first embodiment, frequency conversion is performed in the usual way during the active video period, and the number of horizontal scanning periods in the vertical blanking period is increased/decreased so that the number of horizontal scanning periods composing one frame period is adjusted to be (L+1)×(2N+1). Now, in a case where the number of horizontal scanning periods in the active video period is adjusted, there is a possibility that an increase of the number of horizontal scanning periods in the active video period causes a time lag between writing and reading of an image signal into/from the line memory 202 as shown in
Note that, in the first embodiment, the descriptions have been given on the assumption that the number of horizontal scanning periods composing one frame period in the input video signal is previously determined. However, the number of horizontal scanning periods composing one frame period can be determined in accordance with a format of a video signal (for example, 750P, 1125i, and NTSC). Therefore, the structure shown in
(Second Embodiment)
Now, the number of horizontal scanning periods composing one frame period in an input video signal dynamically fluctuates in some cases. Research performed by the inventors of the present invention reveals that the number of horizontal scanning periods composing one frame period dynamically fluctuates in accordance with a reproducing speed in a case where, for example, a video signal of an analog VTR is reproduced at high speed. Especially, a reproducing speed sharply fluctuates on a frame basis during a transition period from normal reproduction to high-speed reproduction, or a transition period from high-speed reproduction to normal reproduction. Hereinafter, as a second embodiment, a liquid crystal display apparatus capable of handling such a case will be described.
In
In the present embodiment, the number of horizontal scanning periods is individually adjusted in real time on a frame period basis by taking advantage of the fact that a time period from input of a vertical synchronizing pulse to start of the active video period is unchanged even in a case where, like an analog VTR, the number of horizontal scanning periods composing one frame period dynamically fluctuates. First, with reference to
In order to perform real time adjustment for the number of horizontal scanning periods of a video signal whose number of horizontal scanning periods composing one frame period dynamically fluctuates, in the present embodiment, as shown in
In
The period determining section 901 determines, based on the input synchronizing signal, whether or not a signal currently input into the frequency converting section 101 is one corresponding to the adjusting period, and outputs the determination results to the selector 104. Specifically, the determination is made that a period from an input of the vertical synchronizing pulse to a start of the active video period is the adjusting period. Furthermore, the period determining section 901 counts the number Ve of horizontal scanning periods during a period from a start of the active video period to an input of the vertical synchronizing pulse (that is, from a start of counting to an end of counting shown in
The Hr calculating section 902 calculates a dividing clock number Hr used for the adjusting period based on values of Ve, Bp, and Hr, which are supplied from the period determining section 901. Assume that a function F (x,n) is defined as a function returning a value closest to x among values of odd multiple of n, Hr is calculated as follows. Note that L is the number of gate lines into which a non-image signal is concurrently written.
Vr=F(Ve+Bp,L)
Hr=Bp/(Vr−Ve)×Ht
As a result, for instance, Hr=75 in the example of
As hardware realizing the function F, various structures are possible. In a case where n=4 (that is, in a case where L=4), the function F (x,4) can be represented as follows. Note that int (x) is a function returning an integer which does not exceed x.
F(x,4)=int(x/8)×8+4
In this case, int (x/8)×8 can be easily realized by truncating lower-order three bits, whereby it is possible to realize the Hr calculating section 902 using an extremely simple structure as shown in
Based on the determination results of the period determining section, the selector 104 selects the dividing clock number Hr output from the Hr calculating section 902 and supplies it to the frequency converting section 101 during the adjusting period, and selects the dividing clock number Ht output from the period determining section 901 and supplies it to the frequency converting section 101 during a period other than the adjusting period. The frequency converting section 101 generates an output video signal based on the dividing clock number supplied from the selector 104.
As such, according to the second embodiment, it is possible to perform real-time adjustment for the number of horizontal scanning periods of the input video signal, whereby irregularity of brightness does not occur, as is the case with the first embodiment, even in a case of handling a video signal whose horizontal scanning periods composing one frame period dynamically fluctuates.
Note that, in the second embodiment, it is assumed that the adjusting period is a period from an input of the vertical synchronizing pulse to a start of the active video period, but the present invention is not limited thereto. For example, only a back porch may be the adjusting period. However, the shorter the adjusting period becomes, the lower flexibility of adjustment becomes, whereby the adjusting period is preferably the longest possible period.
(Third Embodiment)
As described in the descriptions of the first embodiment, during the vertical blanking period, writing of the image signal is not performed, but the non-image signal is written into pixels of the liquid crystal panel 107 as shown in
With reference to
In order to realize the above-described operation, what is needed is to increase a dividing clock number of the horizontal scanning period corresponding to a timing at which the non-image signal is actually written into the pixels on the liquid crystal panel 107 during the vertical blanking period from 83 (a dividing clock number of the horizontal scanning period in the vertical blanking period in the output video signal shown in
Note that, in the above-described example, as is the case with the first embodiment, it is assumed that the number of horizontal scanning periods composing one frame period of the input video signal is unchanged, but it is possible to apply the third embodiment to a case where, as is the case with the second embodiment, the number of horizontal scanning periods composing one frame period of the input video signal dynamically fluctuates. The structure in that case is shown in
Vr=F(Ve+Bp,L)
Hro=Bp/(Vr−Ve)×Ht
Hr=Hro−(Ht−Hro)/L
In the above-described equations, Hro corresponds to Hr in the second embodiment. In a case where the input video signal is the same as that shown in
The selector 104 selects, based on the determination results of the period determining section 1501, either Ht or Hr, and outputs it to the frequency converting section 101, and the frequency converting section 101 outputs, based on the dividing clock number supplied from the selector 104, an output video signal as shown in
Note that, in the above descriptions, it is assumed that a length of the horizontal scanning period corresponding to a timing at which the non-image signal is actually written into the pixels on the liquid crystal panel 107 during the vertical blanking period is unconditionally the same length of the horizontal scanning period in the active video period. However, if consideration is given only to prevention of inadequate writing of the non-image signal in this period, Ht may be used as the dividing clock number of this period only when Hro<Ht. For example, in a case as shown in
As such, according to the third embodiment, a length of the horizontal scanning period into which the non-image signal is written during the vertical blanking period is controlled so as to be the same length of the horizontal scanning period of the active video period, whereby it is possible to prevent fluctuations of the writing time of the non-image signal, and prevent irregularity of brightness.
(Fourth Embodiment)
Now, in the aforementioned first embodiment, the respective horizontal scanning periods included in the vertical blanking period of the output video signal have uniform lengths, but the number of horizontal scanning periods in the vertical blanking period is increased/decreased, whereby there is a possibility that a length of the horizontal scanning period in the active video period differs significantly from a length of the horizontal scanning period in the vertical blanking period. The greater the difference becomes, the higher the possibility of occurrence of irregularity of brightness becomes. With reference to
In the anti-back-transition driving, writing of one image signal and one non-image signal is alternately performed during one frame period. In
In
The third embodiment is characterized in that the dividing clock number is gradually changed, instead of being changed in a binary manner, as described in the first embodiment, between the active video period and the vertical blanking period. Hereinafter, by taking a case as an example, in which the input video signal is a signal shown in
To the selector 1901, fifteen dividing clock numbers are supplied. These dividing clock numbers are sequentially set, for example, 95, 91, 86, 82, 78, 77, 77, 77, 77, 77, 78, 82, 86, 91, 96, and the selector 1901 switches these dividing clock numbers in a sequential order, and supplies them to the frequency converting section 101 during the vertical blanking period. The total sum of the dividing clock numbers is determined in accordance with the length of the vertical blanking period. For example, in the above-described example, the vertical blanking period is 20×10/50=4 ms, whereby each dividing clock number is set so that the total sum of the dividing clock numbers becomes 312.5 kHz×4 ms=1250. In
As a result of the above-described control, a ratio between the image signal holding period and the non-image signal holding period in one frame period on a line basis is changed into one shown in
(Fifth Embodiment)
In the above-described first to fourth embodiments, it is assumed that the number of horizontal scanning periods is adjusted by controlling the dividing clock number supplied to the frequency converting section 101, but the present invention, which is not limited thereto, can achieve the same effects by switching a clock while fixing the dividing clock number. Hereinafter, as a fifth embodiment, a structure in which the clock to be supplied to the frequency converting section is switched between the active video period and the vertical blanking period will be described.
In
To the selector 2302, a clock A (312.5 kHz) and a clock B (375 kHz), which have different frequencies, are supplied, and the selector 2302 selects either of the clocks in accordance with the determination results of the period determining section 103, and supplies it to the frequency converting section 2301. Specifically, during the active video period, the clock A is output, and the clock B is output during the vertical blanking period.
In
Note that it is assumed that the fifth embodiment has the structure in which the clock is switched by the selector 2302, but the present invention, which is not limited thereto, may have the structure in which a frequency of a single clock is changed, as appropriate, using a PLL, for example.
Now, it is known that applying of a black-level non-image signal to the liquid crystal cells for only a time period predetermined for each frame prevents blurring of moving images, which is typical of a hold-type display element, and enhances a moving image display capability of the liquid crystal panel. The difference between the above-described driving in which the black-level non-image signal is applied to the liquid crystal cells for only a time period predetermined for each frame and the anti-back-transition driving is whether the non-image signal is a black-level signal or a high-voltage signal. Thus, even in a case where the black-level non-image signal is applied to the liquid crystal cells for a time period predetermined for each frame, irregularity of brightness occurs on the same principle as that of the anti-back-transition driving, but it is possible to prevent the irregularity of brightness using the same methods described in the above-described embodiments. Thus, the present invention can be applied not only to driving of the liquid crystal panel in OCB mode, but also to driving of a liquid crystal panel in other modes (for example, TN mode).
As described above, according to the present invention, in a case, for example, where anti-back-transition driving is performed using a liquid crystal panel in OCB mode, it is possible to minimize increase of a driving frequency, prevent irregularity of brightness caused by AC driving of the liquid crystal panel, and reduce cost.
Kobayashi, Takahiro, Ohta, Yoshihito, Arimoto, Katsuyuki, Murao, Tsugio
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